Amino Acids and Proteins PDF

Summary

This document is a chapter on amino acids and proteins. It provides a detailed explanation of amino acid structure, different levels of protein structure including primary, secondary, tertiary and quaternary structure, protein stability, folding and function, and post-translational modifications. It also discusses protein misfolding and diseases.

Full Transcript

Chapter 1-2:
Amino Acids and Proteins
Dr. James Martin II
Assistant Professor, Rowan-Virtua SOM
Email: [email protected]
 Learning Objectives
1. Amino Acid Basics
a) Describe the basic structure of amino acids and categorize them based on their R group properties.

2. Protein Structure
a) Explain the four levels of protein structure: primary, secondary, tertiary, and quaternary.
b) Identify common secondary structure elements (alpha helices and beta sheets).

3. Protein Stability and Folding
a) Discuss the main forces that stabilize protein structure.
b) Explain the basic concept of protein folding and factors that can lead to denaturation.

4. Structure-Function Relationships
a) Describe how protein structure relates to function, using examples like enzymes or structural proteins.

5. Protein Modifications
a) Explain the concept of post-translational modifications and their significance.

6. Protein Misfolding and Disease
a) Discuss the relationship between protein misfolding and certain diseases.
Part 1 - Amino Acids
Structure and Chemistry

Building Blocks of Proteins

Essential Amino Acids

Basic Structure

Stereochemistry

Side Chain Chemistry

Properties

Ionization

Bonding
Amino Acids & Proteins
Workhorses of cell
– Catalysis
– Signaling
– Structure
– Energy/Gradient Generation
Proteins comprised of 20-21 amino acids
Amino Acids
Essential Amino Acids
 Alpha Carbon
Basics of Structure
Elements Alpha Carboxyl

Alpha Amino Acids

Differences in R Groups
Alpha Amine
 Alpha Carbon
Basics of Structure
Elements Alpha Carboxyl

Alpha Amino Acids

Differences in R Groups
Alpha Amine
Examples
Asymmetric Center

Alpha Carbon Alpha Carboxyl

R

Alpha Amine
 Alpha Carbon
Basics of Structure
Elements Alpha Carboxyl

Alpha Amino Acids

Differences in R Groups
Alpha Amine
Examples
Asymmetric Center

Alpha Carbon Alpha Carboxyl

R
18
Alpha Amine
 o n
rb
Amino Acids C a
Stereochemistry ri c
et
m
D and L Isomers y m
A s

Almost all biological amino acids
are in the L-configuration
Categorizing Amino Acids

Non-Polar Carboxyl Amine Aromatic Hydroxyl Other

Alanine Aspartic Acid Arginine Phenylalanine Serine Asparagine

Glycine Glutamic Acid Histidine Tryptophan Threonine Cysteine

Isoleucine Lysine Tyrosine Tyrosine Glutamine

Leucine Selenocysteine

Methionine Pyrrolysine

Proline

Valine
Ionizable R-groups
Name Charged R-group Approximate R-group pKa

-
Aspartic Acid -COO 4.1
-
Glutamic Acid -COO 4.1

+
Lysine -NH3 10.5
+
Arginine =NH2 12.5
+
Histidine =-NH 6.0
-
Cysteine -S 8.2

-
Tyrosine -O 10.5
Amino Acids
Aromatic R-Groups

Alpha Carbon
Tryptophan

Alpha Amine
Alpha Carboxyl
Tyrosine Phenylalanine
Amino Acids R
Aromatic R-Groups

Tryptophan
R R

Tyrosine Phenylalanine
Amino Acids R
Aromatic R-Groups
Charges at Physiological pH

Tryptophan
R R

Ionizes at high pH Tyrosine Phenylalanine
Amino Acids
Aliphatic R-Groups

H

Alanine Glycine Proline Isoleucine

Leucine Valine Methionine
Amino Acids
Aliphatic R-Groups

H

Alanine Glycine Proline Isoleucine

Leucine Valine Methionine
Amino Acids
Aliphatic R-Groups
Charges at Physiological pH
Amino Acids
R-Group Carboxyls

Aspartic Acid Glutamic Acid
Amino Acids
R-Group Carboxyls

R
R

Aspartic Acid Glutamic Acid
Amino Acids
R-Group Carboxyls
Charges at physiological pH

R
R

Aspartic Acid Glutamic Acid
Amino Acids
Hydroxyl R-Groups

Serine

Threonine

Tyrosine
Amino Acids
Hydroxyl R-Groups

Serine

Threonine

Tyrosine
Amino Acids
Hydroxyl R-Groups
Charges at Physiological pH

Serine

Threonine

Ionizes at high pH

Tyrosine
Amino Acids
Sulfhydryl R-Group

Cysteine
Amino Acids
Sulfhydryl R-Group

Ionizes at about pH = 8

+
Cysteine
Amino Acids
Carboxamide R-Groups

Asparagine Glutamine
Amino Acids
Carboxamide R-Groups

Asparagine Glutamine
Amino Acids
Carboxamide R-Groups

Asparagine Glutamine
Amino Acids
Ionizable Amine R-Groups

Arginine

Lysine

Histidine
Amino Acids
Ionizable Amine R-Groups

Arginine

Lysine

Histidine
Amino Acids
Ionizable Amine R-Groups
Charges at Physiological pH

Arginine

Lysine

Histidine
Rare Amino Acids
Non-Protein Amino Acids

Carnitine

Also - Citrulline, Ornithine, others
Amino Acids
Ionization
Amino Acids
Ionization -by pKa Values
Amino Acids
Ionization -by pKa Values
Amino Acids
Ionization -by pKa Values
Amino Acids
Ion Locations in Titration

Charge = -1
Amino Acids
Ionization -by pKa Values

Charge = 0
Amino Acids
Ionization -by pKa Values

Charge = -1
Amino Acids
Ionization -by pKa Values

Charge = -2
Ionization Changes Charges Within Proteins

Changes in Charge Change Activities
Post-translational Modifications
Phosphorylated Amino Acids
Breakdown of Amino Acids
From Amino Acids to Proteins
Peptide Bonds

In Ribosomes
Alpha Carboxyl Alpha Amine
Primary Protein Structure

Linear sequence of amino acids
Joined by Peptide Bonds
Translated from mRNA using Genetic Code
Synthesis begins at amino end and
terminates at carboxyl end
Ultimately determines all properties of a
protein
Polypeptides Alternating Orientations of R-groups
A simple view

Peptide Bond Peptide Bond
Free Carboxyl Group
Amino Terminus Peptide Bond

Carboxyl Terminus

Peptide Bond Peptide Bond
Free Alpha Amine

Alternating Orientations of R-groups
Peptide Bonds
Chemical Character

Double Bond Behavior

Alpha Carbons Usually
Trans-oriented
 Separated bulky groups
Proteins Alpha Carbons Trans
Steric Hindrance

Separated bulky groups

Interacting
Bulky
Groups

Alpha Carbons Cis
Polypeptides
Multiple Peptide Bond Planes

Free Rotation
Phi and Psi Angles
Peptide Bond
Omega Angle
Psi Angle
Phi Angle

Peptide Bond
Ramachandran Plot
Bond Angles

Primary Angles
of Stability
Secondary Structure
Alpha Helix
Secondary Structure
Alpha Helix

Hydrogen bonds
stabilize structure
Hydrogen bonds
stabilize structure
 Hydrogen Bonds
Secondary Structure
Beta Strands / Beta Sheets

Anti-Parallel Parallel
Beta-Sheet Interactions
Secondary / Supersecondary Structures
Ramachandran Plot Labeled
Secondary Structure
Fibrous Proteins

Collagen
Connective tissue
Keratin
Hair / nails
Fibroin
Silk
 Collagen Partial Sequence

Primary Structure
Hydroxyproline
Proline in Helix
Abundant Glycine
Occasional Lysine
Structural Proteins

Keratins
Fibrous
50 in Humans
Intermediate Filaments of Cytoskeleton
Hair, nails, horns
Fibroin

Silk
Beta sheets
Repeating glycines
Secondary Structure Types

Alpha Helix
Beta Strands / Beta Helix
Reverse turns (5 types)
310 Helix
Secondary Structure
Tendencies of Amino Acids

High Propensity for
Alpha Helices

High Propensity for
Reverse Turns
High Propensity for
Beta Strands
Amino Acid Hydropathy
Soluble vs. Membrane Bound Proteins

Hydrophobic Amino
Acid Bias Inside

Hydrophilic Amino
Acid Bias Outside

Hydrophobic Amino
Acid Bias In Bilayer

Hydrophilic Amino Acid
Bias Outside of Bilayer
Reverse Turns
Tertiary Structure
Folding and Turns

Beta Strands

Alpha Helices

Random Coil
Turns
Folding of a Globular Protein
Unfolding of a Globular Protein
Forces Stabilizing Tertiary Structure

Hydrogen Bonds
Forces Stabilizing Tertiary Structure

Disulfide Bonds (Covalent)
Forces Stabilizing Tertiary Structure
Denaturing/Unfolding Proteins

Break forces stabilizing them
Mercaptoethanol/dithiothreitol - break disulfide bonds
Detergent - disrupt hydrophobic interactions
Heat - break hydrogen bonds
pH - change charge/alter ionic interactions
Chelators - bind metal ions
Denaturing/Unfolding Proteins
Folding of a Globular Protein
Energetics of Folding
Protein Structural Domains
Leucine Zipper - Prot.-Prot. and Prot.-DNA
Helix Turn Helix - Protein-DNA
Leucine Zipper
Zinc Fingers
SH2 Domains - Protein-Protein
Pleckstrin Homology Domains - Signaling (Membrane)

Leucine Zipper
Zinc Finger

SH2 Domain
Helix-Turn-Helix
Pleckstrin Domains
Folding Errors
Prion Replication Model
Amyloids and Disease

Amyloids - a collection of improperly folded protein aggregates found in the human body.
When misfolded, they are insoluble and contribute to some twenty human diseases including
important neurological ones involving prions.
Amyloid diseases include (affected protein in parentheses) -

Alzheimer’s disease (Amyloid β)

Parkinson’s disease (α-synuclein)

Huntington’s disease (huntingtin),

Rheumatoid arthritis (serum amyloid A),
Sc
Fatal familial insomnia (PrP )
Protein Processing

Chaperonins - Proper folding - environment for hydrophobic sequences

GroEL / GroEL-GroES

Proteasomes - Degradation to oligopeptides of about 8 amino acids each
Role of Ubiquitin

Flag for protein destruction by proteasome
Intrinsically Disordered Proteins

Not all proteins folded into stable structures
Intrinsically Disordered Proteins (IDPs) have regions favoring disorder
IDP regions tend to lack hydrophobic residues
Rich in polar amino acids and proline
IDPs may favor adaptation to binding another protein
IDPs may favor being modified
IDPs may be more involved in signaling and regulation
Non-IDPs more involved in catalysis and transport

Metamorphic Proteins
May adopt more than one stable structure
Lymphotactin - monomeric receptor. Binds heparin as dimer
Protein Structure

Primary – Amino Acid Sequence
Secondary / Supersecondary – Repeating Structures – short range forces
Tertiary – Folded structures – longer range interactions